Antenna transportable system



July 26, 1966 N. w. BURWELL. ETAL 3,263,232

ANTENNA TRANSPORTABLE SYSTEM Filed May 24, 1962 5 Sheets-Sheet 1 INVENTOR' July 26, 1966 N. w. BURWELL ETAL 3,253,232

ANTENNA TRANSPORTABLE SYSTEM Filed May 24, 1962 5 Sheets-Sheet 2 July 26, 1966 N. w. BURWELL ETAL 3,263,232

ANTENNA TRANSPORTABLE SYSTEM Filed May 24, 1962 5 Shee'cs-Sl'lee'l 3 I N VEN TOR5 /VEM MaPh/u July 26, 1966 N, w BURWELL ETAL 3,263,232

ANTENNA TRANSPORTABLE SYSTEM Filed May 24, 1962 5 Sheets-Sheet 4 July 26, 1966 N. w. BURWELI. ETAL 3,263,232

ANTENNA TRANSPORTABLE SYSTEM Filed May 24, 1962 5 Sheets-Sheet 5 Fr 51.73A

United States Patent 3,263,232 ANTENNA TRANSPORTABLE SYSTEM Neil W. Burwell, Southampton, and Charles Fassnacht,

Phiadelphia, Pa., assignors, by mesne assignments, to

Washington Aiuminum Co., Inc., Baltimore, Md., a

corporation of Delaware Filed May 24, 1962, Ser. No. 197,477 13 Claims. (Cl. 343-713) This invention relates to a mobile antenna system, and more particularly to such an antenna system wherein the system carrying transport trailer may be readily converted to form the prime elevated support structure thereof.

The mobility requirements of many electronic communications systems necessitate an antenna system that may be readily transported to and assembled at a designated installation site. To increase antenna range, such installations usually require an appreciable elevation of the antenna with respect to the ground surface. One arrangement of the prior art to obtain such an elevated system is to erect a separate tower at the installation site and install a trailer transported antenna system on such a tower. This arrangement does not utilize the trailer itself, therefore resulting in an inefficient system concept requiring trailer stowage at the site. Also such separate towers of the prior art typically require a complicated arrangement of guys to stabilize the system and provide the necessary azimuth and elevation adjustments.

Another arrangement of the prior art is to use the existing trailer as the base for the antenna erection. This arrangement permits little height advantage and since it uses the trailer as a foundation only, results in considerable weight which serves little or no structural value.

In our system the complete trailer chassis is converted into an elevated support structure, thereby yielding an improved structure avoiding many of the disadvantages of the prior art arrangements. The assembly procedure is preferably reversible, allowing the erected antenna to be easily disassembled for convenient movement of the entire system to another site.

Briey stated the trailer chassis utilized of our invention is formed of a plurality of supporting legs, which may be disassembled as a trailer chassis and constructed to form an elevated structure to contain the antenna reflector and associated R-F equipment. In a preferred embodiment of our invention the reilecting surface is formed of a plurality of members, which may also be disassembled to be contained within the support leg formed transport chassis. Thus, the entire antenna system may be contained on a trailer chassis which is transported t-o the installation site, and all the members thereof utilized to form the antenna installation. Full use is made of the trailer as a prime structural member, and after the equipment is installed, it becomes an extremely rugged tower capable of withstanding high wind and ice loads. The utilization of the transport trailer itself as the prime structural member effects a considerable weight and material ,saving over the prior art systems which elevate the antenna reflector to a comparable height.

An additional feature of our invention is the use of a cable and winch assembly, in conjunction with a lifting jack, to erect the antenna support structure. The lifting jack may serve the dual function of interconnecting the antenna reector to the support structure, after erection thereof, to provide a reflector elevation adjustment. Also, the unit is completely self-contained, does not require an external power source or vehicle to accomplish the erection, with all necessary equipment being furnished on the transport trailer.

rice

In an illustrated embodiment of our invention, the basic support structure is a tripod consisting of rectangular open-lace aluminum .structural legs, which may be attached along their length in a spaced parallel juxtaposed relationship to form the transport trailer chassis. One of the legs contains the necessary wheel axles and running gear to permit transportation thereof. A tow bar with a standard lunette eye is provided for attachment to a prime mover vehicle.

To erect the antenna system the tripod forming legs are disassembled from their juxtaposed relationship and connected peripherally about a central hub in a starlike manner. The antenna reilector and associated R-F equipment is assembled and connected to the top surface of the central hub. The rear leg, which contains the wheel axles, is pivotally attached to the central hub and the two front legs hooked onto the central hub. A lifting jack then raises the central hub `sufficiently to rigidly secure the two front legs to mating separated surfaces of the central hub. The remotely extending ends of all the legs are then interconnected by a cable assembly, with the lifting jack being removed as soon as the tension has been taken up by the cables. The assembled antenna reector is secured to the central hub and preferably interconnected thereto by the lifting jack which is arranged to permit an elevation adjustment of the antenna reflector. the rear leg towards the front legs while it. rolls on its wheel suspension, thereby elevating the central hub. The front leg is then rigidly secured to a mating surface of the central hub to maintain its position and prevent collapse of the tripod. Ground anch-ors may .then be added lfor increased wind resistance.

The above described procedure is completely reversible. That is, the rigid securing means of the pivoted leg to the central hub may be disengaged and the elevated tripod structure lowered. The other two legs are then disconnected from the central hub. The legs are then connected in spaced parallel juxtaposed relationship to form the transport trailer. The R-F equipment may then be disassembled and placed on the leg-formed trailer chassis. The wheel axles and running gear remain on one of the structural legs, permitting immediate transportation of the disassembled system.

It is thus `seen that the basic concept of our invention resides in the use of the transport trailer itself as the prime support member for a mobile antenna system. `The trailer and all the members of the antenna system are interrelated to permit a complete system, including the erection means and R-F equipment to be contained on the supp-ort structure formed trailer chassis which is delivered to the installation site.

It is therefore a primary object of this invention t-o provide a mobile antenna system wherein the transport chassis may be disassembled and converted to form an antenna carrying elevated support structure.

Another object of this invention is to provide a mobile antenna system wherein the transport trailer is formed of three separate elongated structural members which may be disassembled and constructed to form a tripod antenna support structure.

A further object of this invention is to provide a mobile antenna system wherein the support `structure members form the transport trailer containing the antenna reflector, R-F equipment and elevating means.

An additional object of this invention is to provide a mobile antenna system wherein the trailer chassis may be converted to serve as an elevated support structure, and no external power means are required to elevate the support structure.

Still another object of this invention is to provide a mobile antenna system having an elevated support struc- The cable assembly draws ture which may readily be converted to form a transport chassis.

Still a further object of this invention is to provide a mobile antenna system including an elevated support structure which may be converted to a trailer chassis, the en- -tire antenna system being transported to or from the installation site on that trailer chassis.

Still an additional object of this invention is to provide an antenna support structure which may be readily assembled from a trailer chassis by the utilization only of connecting bolts and a cabling arrangement, said assembly process being reversible.

These as well as other objects -of the invention will become readily apparent after reading the following descriptions of the accompanying drawings in which:

f FIGURE 1 is a perspective view of the erected antenna system built in accordance with the teachings of our invention.

FIGURE 2 is a cross section along line 2--2 of FIG- URE 1 and looking in the direction of the arrows, which shows the connection of the support legs to the central hub.

FIGURE 3 is a perspective view of the trailer chassis, constructed of the tripod forming legs of the support structure.

FIGURES 4 and 5 are plan and elevation views respectively of FIGURE 3, with the addition of the reflector forming members, and associated R-F equipment, as delivered to the installation site.

FIGURES 6-9 successively show the erection of our antenna system.

FIGURE l schematically shows a reflector andy feed system utilized in conjunction with our invention.

FIGURE 11 illustrates the radial supporting rib of a preferred reflector structure which may be utilized in conjunction with the antenna system of our invention.

FIGURES 12-15 depict structural details of the reflector structure `of FIGURE 1l with: FIGURES 12 and 12A showing the connection of the radial rib to the central reflector hub; FIGURES 13 and 13A showing the intermediate support structure between the reflective surface and radial rib; FIGURE 14 showing the intercostal support connection between the reflective surface and radial rib; and FIGURE 15 showing the connection of the ribs about the central reflector hub and support frame.

FIGURE 16 illustrates a typical dual polarized feed horn which may be utilized in conjunction with our invention.

Referring initially to FIGURE l, antenna system 20 comprises a support structure 30, reflector 50 and an R-F antenna feed 55. Reflector 50 is interconnected to central hub 31 of structural member 30 by an interconnection means generally shown as 60. A plurality of legs, preferably three in number, 32, 33, 34, are connected to raised central hub member 31. A wheel and axle transport means 35,35 is permanently secured to one 0f the legs 32 of the structure support 30. Thus it is seen that antenna reflector 50 and R-F feed 55 are elevated by structure 30.

FIGURE 2 depicts a preferable connection of support legs 32-34 to central hub 31.- Central hub 31 contains 120 separated surfaces 45 which mate with similarly constructed leg end surfaces 39 (best shown in FIGURES 3 and 7). Gusset plates 42 disposed in each of corners of surfaces 39 and 45 contain apertures to receive bolt means 42'; preferably two in each gusset plate. The interconnection of each of the legs 32-34 to central hub 31 by the eight bolt means 42 through gusset plates 42 provides an extremely rigid connection able to withstand considerable loading. A pivot rod 41 interconnects leg 32 and hub 31, the purpose fof which will be set forth below.

Referring now to FIGURES 3-5 it is seen that structural member 30 forms a trailer chassis 70 prior to erection thereof, support legs 32, 33, 34 are positioned in juxtaposed spaced parallel relationship and attached along their length thereof lby bolt means 36, extending through mating apertures in the open-lace constructed legs. Reflector 50 is contructed of a plurality of members which when disassembled may be stacked on the leg formed trailer chassis 70, as best shown in FIGURE 5. Radial ribs 51 and reflector face panels sections 52 are shown stacked at the front and rear portions of the trailer, respectively. R-F feed 55 is shown interposed between the face panel stacks.

Transport means 3S, 35', which is permanently secured t0 central leg 32, contains all the running gear, air-over hydraulic ybrake equipment and electrical equipment for the requisite trailer lighting. All the running gear remains intact on this leg section when it is later erected, and therefore dispenses with the requirement of disconnecting air or electrical lines within the leg. Preferably, a four-wheel type suspension is utilized with the front and rear Wheels 35, 35 being located relatively near their respective ends of the trailer. The rear suspension is preferably of a conventional fixed axle-type wheel and the front suspension of a fifth wheel type. Hence, the turning radius of the trailer will therefore only be limited by the braking lines leading to the fifth-wheel axle, since this wheel is capable of 360 rotation. A towing tug 37 is provided for attachment to a prime mover vehicle, with a standard lunette eye 38 at its open end.

Each of the legs 3235 are of rectangular open-lace construction and include slope ends 39 having bolt receiving gusset plates 42 in each corner thereof, as discussed in conjunction with FIGURE 2. End 40 contains a ball joint 43 adapted to be connected to a bearing pad 44 (see FIGURE l). Central hub 31 is preferably permanently pivoted to leg 32 by pivot rod 41. Members 31-34, as well as all other structural members discussed below, are preferably formed of aluminum for weight reduction and increased resistance to environmental conditions.

Reference is now made to FIGURES 6-9 which successively illustrate the manner in which the trailer chassis 70 is converted to the prime support structure 30. The reflector 50 and associated R-F equipment is first removed from lthe trailer bed and assembled, in the manner that will be more fully set forth below. Bolt means 36 are disconnected permitting the removal of front legs 3.3 and 34 from rear leg 32. Lifting handles may be provided to facilitate such handling. Center hub 31 is pivoted about 41 from the stowage position shown dotted in FIGURE 6. The reflector interconnecting support frame 61 is connected to the top of center hub 31, and the assembled reflector 50 connected thereto. Hooks 47 at ends 39 of front legs 33, 34 are placed 4at the top of their respective surfaces 45 of central hub 31 to position those legs about the hub.

The structure will now be in the star-like position of FIGURE 7. The legs 32-34 are shown spread apart about separated surfaces 45 of central hub 31 which mate with similarly shaped surfaces at leg end 39. Rear leg 32 is pivoted thereto by rod 41, and front legs 33, 34 positioned by hooks 47. It is apparent from this figure that as the ends 40 of the legs are brought together, central hub 31 will be elevated, thereby forming a tripod structure with the antenna reflector secured to that member.

A screw jack 62 is inserted into a lifting lug of the reflector support 61 (as shown in FIGURE 6) to provide sufficient elevation of centr-al hub 31 for the rigid connection thereto of front legs 33 and 34 at their bolt receiving gusset plates 42. The structure yis quite stable at this point due to the fact that the two front legs 33, 34 are rigidly attached to central hub 31. This prevents overturning and eliminates the need for tag lines or other supports during the erection procedure.

A hoisting cable assembly 46, `as shown in FIGURES 8 and 9, is interconnected between the ends 40 of tripod forming legs 32-34 to provide for the bringing together of the support legs. In the particular cable interconnection shown, cable assembly 46 includes a plurality of individual cables connecting the legs 32-34 to ring attachments 47, 47. A Winch, such as hoist 48, provides the tensioning force for drawing the legs together and thereby raising hub 31. An equalizing ring pulley 49 is preferably added at leg 32. This cabling arrangement advantageously utilizes the toggle action as the structure is elevated to maintain a nearly constant pulling force. Alternatively, other cable arrangements may be employed to erect the tripod, such as a single cable interconnecting all the legs, with an intermediate winch to provide the tensioning force for pulling the legs together.

Once sufficient tension is obtained in cable assembly 46, jack 62 may be removed and repositioned as shown in FIGURE 8 to provide elevation adjustment of reflector 50. Alternatively, a separate jack may be provided for lifting of the structure and reflector elevation adjustment. The front leg 32 is gradually drawn inward by winch 48 as it rolls on its front suspension 35 as the angular -displacement of the pivotal connection at 41 is gradually lessened until end 39 of leg 32 is flush against the similarly contoured surface 45 of central hub 31. The structure will now be in the fully elevated position shown in FIGURE 1. Bolt means 42 `are then inserted in gusset plates 42 of rear leg 32 to provide a stabilized structure.

Ball and socket joints 43-44 are provided to maintain stabilization of the structure against considerable winds. Base pad 44 of rear leg 32 will also provide ground clearance of wheel and axle assembly 3S when the antenna is in the erected position. If desired additional ground anchors may be provided for increased wind resistance of the antenna structure.

Azimuth pivot 63 of reflector interconnector 60 permits the requisite orientation of the reiiector in accordance with the particular requirements of the system. The azimuth pivot 63 and the elevation jackscrew 62 permit an easy adjustment of reflector orientation, by simply rotating the nut of the elevation jackscrew, or adjusting the turnbuckle on the azimuth mechanism.

Feed 5S is preferably added to the antenna system after complete elevation of support structure 30, to minimize the requisite cable pulling force. Feed 55 is supported at the base of reliector 50 by a hinged bracket 65, providing a convenient method for pivoting the feed system in place, and permitting lowering for boresighting and maintenance. Feed 55 is rigidly connected to reflector 55 by a three-point suspension system which includes a dual horizontal bar arrangement and a dual wave guide run to the bottom of reflector 50 to constitute a stable structure for the hom when subjected to severe wind loading.

In summary, the erection procedure may be followed by sequentially referring to FIGURES 5, 4, 3, 6, 7, 8, 9 and l. The complete antenna system is delivered to the site, as shown in FIGURES 5 and 4, and unloaded from the basic trailer chassis shown in FIGURE 3. The central hub 31 is pivoted as shown in FIGURE 6 and the support legs of the disassembled trailer positioned in starlike manner about central hub 31, as shown in FIGURE 7. The front legs 33, 34 are rigidly secured to central hub 31 and the oppositely extending ends of the legs interconnected by cable assembly 46, as shown in FIG- URE 8. The cable assembly 46 draws rear leg 32 towards the other legs, yas it .slides on its front suspension, thereby elevating hub 31, as shown in FIGURE 9. Rear leg 32 is then secured to central hub 31 and the feed assembly 55 connected to antenna reflector 50, as shown in FIGURE 1.

The entire assembly procedure is completely reversible, permitting an existing antenna system to be readily disassembled and placed on its formed trailer chassis for transportation to another installation site. The permanent connection of transport means 35, 35 on leg 32 facilitates such subsequent transportation.

Referring to FIGURE l0 the antenna 50 and feed 55 are operatively connected to support member 61, which is adapted to be `connected to central hub 31. As will be more fully discussed below in conjunction with FIGURE 15, support member 61 is an A-frame, and incorporates the azimuth and elevation adjusting mechanisms discussed above. Feed 55 is illustratively shown as a dual polarized feed with wave guides 56 and 57 connected to horn S8. Horn 58 will preferably inclu-de deicing terminal box 59, should the antenna be installed at a site Where the environmental conditions necessitate this function.

FIGURES 11-14 illustrate a preferred reflector embodiment which may be used in conjunction with our invention. This embodiment has the particular advantage that the reector components may be disassembled and mounted on the transport trailer '70, as shown in FIGURES 4 and 5. Also, complete interchangeability of parts is utilized to facilitate the assembly of the reflector system. All the hardware utilized in the reector assembly is preferably stainless steel for increased environmental rcsstance.

Reflector 50 is comprised of a number of pie-shaped reector plates S2, Which are adjacently arrayed to form the outer `annular region of parabolic reliecting surface 50, with a central spun aluminum dish 77 at its center. An overlapping lip is preferably added to a radial edge of each of the face panels 52 to assure R-F surface continuity across the gap between these panels.. This overlapping lip is preferably backed with a dielectric material to avoid sporadic contact and resulting noise generation. Reflecting plates 52 are connected to a similar plurality of supporting ribs 51 extending outward from central reflector hub 53. Ribs 51 preferably bisect the joint between two adjacent face panels 52. The construction of one such rib 51 and the attachment of the reflector plate 52 thereto are shown in FIGURE l1. Face panels 52 are directly attached to ribs 51 by a plurality tof intercostal circumferential rings 54 and intermediate support members 56.

FIGURES V13 and 13a illustrate the connection of intermediate support member 56 to face panel 52. Channel bracket stand-off 57 is welded to rib 51 and is positioned to be connected to a mating threaded self-locking heli-coil insert 58 attached to reflector plate V52. Channel bracket 57 is then bolted to rib 51 by the insertion of a standard socket wrench in access 59.

FIGURE 14 illustrates the connection of the intercostal members 54. Ring costal member 66 is connected by bolts 67, 67 to reflector section 52 and to stand-olf 78 Welded to rib S1. Opening 68 in rib 51 provides socket wrench access to bolt 67.

FIGURES 12 and 12a illustrate the connection of the peripherally disposed ribs 51 to central reilector hub 53. Central reector hub 53 contains a plurality of precision-matched flat surfaces 69 equally spaced and adapted to receive the mating flat surface of rib 51. Bolts 70 securably attach the ribs 70` to central reflector hub 53.

FIGURE '15 is a plan schematic showing the connection lof ribs 51 to central -hub 53 and their relationship with respect to support member 61. Support member 61 is an A-frarne and includes azimuth hinge pin 63 and elevation hinge pin 71, the latter being connected to jack 62, to permit adjustment of reflector position.

FIGURE 16 illustrates a typical horn structure which may be used in conjunction with our invention. Horn S8 is of the `type described in copending U.S. patent application (A-l08) Serial No. 166,205 filed January 15, 1962 in the name of David F. Bowman, entitled Microwave Signal Transfer Apparatus and assigned to the assignee of the instant invention, in which dual polarized signals entering wave guide ports 73, 74 are combined by spear 7S to yield a composite dual polarized signal at aperture 76. Septurn 79 provides improved impedance matching at the transition region. vided for a deicing terminal box.

It is therefore seen that we have Iprovided a mobile antenna system, wherein the entire disassembled structure is transported to the installation site on a trailer chassis, and the chassis may be converted to form a rugged elevated tripod structure capable of withstanding high wind and ice loads.

A practical working embodiment of the instant invention has been designed for a troposcatter communication antenna system operating in the 755 to 985 megacycle range and utilizing WR 975 waveguide runs. The maximum weight of the loaded trailer including the entire antenna system is 8,000 pounds. Each of the support legs are 30 feet long and weigh approximately 300 pounds. When erected, the tripod struct-ure has a 40 foot base which may be stabilized in winds up to 120 miles per hour, with only three ground anchors, and is stable without anchors in winds up to 30 miles per hour. The refiector is a 28 foot dish having an F/D ratio of 0.414. It is constructed of 24 sectorial pie sections, each having a 1/li-inch thick aluminum preformed surface. Each face panel weighs approximately 60 pounds, and each supporting rib approximately S pounds. The complete erection of the antenna system, or breakdown and restowage on the trailer, is designed to be accomplished within a single day.

In the foregoing disclosure this invention has been described with a preferred illustrative embodiment. Since many variations and modifications will now become apparent to those skilled in the art, we prefer therefore not to be limited to the specific disclosure contained herein but only by the appended claims.

We claim:

1. A mobile support structure comprising: a first, second and third leg; a first means constructed to fasten said legs directly to one another in spaced parallel relationship along t-he length thereof to form a trailer to for-m a trailer chassis; each of said legs having longitudinally extending top, ybottom and side surfaces; said first means fastening side surfaces of adjacent legs in face-to-face relationship, with a side surface of said first leg facing a side surface of said second leg, and a side surface `of said third leg facing the opposed side surface of said second leg; wheel axle transport means directly securable to the bottom surface of at least one of said legs for movement of said leg-formed -trailer chassis; tand a second means constructed to fasten said legs in a tripod manner.

2. A mobile support structure comprising: a first, second and third leg; a first means constructed to fasten said legs directly to one another in spaced parallel relationship along the length thereof to form a trailer chassis; each of said legs having longitudinally extending top, bottom and side surfaces; said first means fastening side surfaces of adjacent legs in face-to-face relationship', with a side surface of said first leg facing a side surface of said second leg, and a side surface of said third leg facing the opposed side surface of said second leg; wheel axle transport means directly securable to the bottom surface of at least one of said legs for movement of said legformed trailer chassis; and a second means constructed to fasten said legs in a tripod manner; said first and second means including removably connected bolts.

3. In a mobile antenna system a support structure comprising: a first, second and third leg; a first means constructed to fasten said legs directly to one another in spaced parallel relationship along the length thereof to form a trailer chassis; each of said legs having longitudinally extending top, bottom and side surfaces; said first means fastening side surfaces of adjacent legs in faceto-face relationship, with a side surface of Lsaid first leg facing a side surface of said second leg, and a side surface of said third leg facing the opposed side surface of said second leg; wheel axle transport means directly Housing 59 is prosecurable to the bottom surface of at least one of said legs for movement of said leg-formed trailer chassis; and a second means constructed to fasten said legs in a tripod manner about a central hub; said central hub constructed to receive an antenna reflector, feed, and refiector positioning means.

4. A mobile support structure comprising: a first, second and third leg and a central hub; means positioning said legs about said hub in a star-like manner; elevating means constructed to raise said central hub whereby said legs define a tripod; said elevating means adapted to permit the lowering of said tripod -whereby some of said legs may be disconnected from said central hub and fastened in spaced parallel relationship to form a trailer chassis; transport means permanently connected to one of said legs; said transport means including a plurality of wheel axles, each having a pair of rotatively supported wheels.

5. A mobile support structure comprising: a plurality of elongated supporting legs each having a first and second end; a first means to fasten said legs directly to one another in spaced parallel juxtaposed relationship along the length thereof, between said first and second ends, to form a trailer chassis; each of said legs having longitudinally extending top, bottom and side surfaces; said first means fastening the side surfaces of adjacent legs in face-to-face relationship, with the top surfaces thereof lying substantially within a common horizontal plane; transport means connected to the bottom surface of at least one of the legs of said leg formed trailer chassis; said first means permitting disassembly of said leg formed trailer chassis; a central hub; a second means constructed to fasten the fiirst ends of each of said legs to said hub to form an elevated support structure.

6. A mobile support structure comprising: a plurality of elongated supporting legs each having a first and second end; a first means to fasten said legs in spaced parallel juxtaposed relationship along the length thereof, between said first and second ends, to form a trailer chassis; each of said legs having longitudinally extending top, bottom and side surfaces; said first means fastening the side surfaces of adjacent legs in face-to-face relationship, with the top surfaces thereof lying substantially within a common horizontal plane; transport means connected to the bottom surface of at least one of the legs of said leg formed trailer chassis; said first means permitting disassembly of said leg formed trailer chassis; a central hub; a second means constructed to fasten the first ends of each of said legs to said hub to form an elevated support structure; and a third means adapted to progressively draw the second ends of said legs together, whereby said central hub -is elevated with respect to the second ends of said legs.

7. A mobile support structure comprising: a plurality of elongated supporting legs each having a first and second end; a first means to fasten said legs in spaced parallel juxtaposed relationship along the length thereof, ybetween said first and second ends, to form a trailer chassis; transport means connected to said leg formed trailer chassis; said first means permitting disassembly of said leg formed trailer chassis; a central hub; a second means constructed to fasten the lfirst ends of eac-h of said legs to said hub to form an elevated support structure; said first end of said legs having a generally rectangular cross section; said hub having a plurality of peripherally disposed similar rectangular surfaces, one for each of said legs and in abutting relationship therewith; the first end of each of said legs and its cooperating one of said rectangular surfaces joined together in a generally vertical plane; the vertical planes of successive ones of said legs and cooperating hub surfaces peripherally spaced about said central hub.

S. A mobile antenna system comprising: a plurality of elongated supporting legs each having a first and second end; a first means to fasten said legs in spaced parallel juxtaposed relationship along the length thereof, be-

tween said first and second ends, to form a trailer chassis; transport means connected to said leg formed trailer chassis; said first means permitting disassembly of said leg formed trailer chassis; a central hub; a second means constructed to fasten the first ends of each of said legs to sa-id hub to form an elevated support structure; a third means adapted to draw the second ends of said legs together, whereby said central hub is elevated with respect to the second ends of said legs; said ilrst end of said legs having a generally rectangular cross section; said hub having a plurality of peripherally disposed similar rectangular surfaces, one for each of said legs and in abutting relationship therewith; the ilrst end of each of said legs and its cooperating one of said rectangular surfaces joined together in a generally vertical plane; the vertical planes of successive ones of said legs and cooperating hub surfaces peripherally spaced about said central hub; said hub having a horizontally disposed top surface adapted to receive an antenna reflector; and a fourth means -operatively connected between said reflector and reflector receiving hub surface to permit motion of said reflector with respect to said central hub.

9. A mobile antenna system comprising: a plurality of elongated supporting legs each having a first and second end; a first means to fasten said legs in spaced parallel juxtaposed relationship lalong the length thereof, between said first and second ends, to form a trailer chassis; transport means connected to said leg formed trailer chassis; said rst means permitting disassembly of said leg formed trailer chassis; a central hub; a second means constructed to fasten the first ends of each of said legs to said hub to form an elevated support structure; a third means adapted to draw the second ends of said legs together, whereby said central hub is elevated with respect to the second ends of said legs; said first ends of said legs having a generally rectangular cross section; said hub having a plurality of peripherally disposed similar rectangular surfaces, one for each of said legs and in abutting relationship therewith; said hub having a surface adapted to receive `an antenna reflector; and a fourth means operatively connected between said reflector and reflector receiving hub surface to permit motion of said reflector with respect to said central hub; said reflector being constructed of a plurality of individual members adapted to be assembled lby bolt means; said leg formed trailer chassis being dimensioned to contain said individual reflector members prior to assembly of said reflector.

10. A mobile support structure comprising: a plurality of elongated supporting legs each having a first and second end; a rst means to fasten said legs -in spaced paral- -lel juxtaposed relationship along the length thereof, between said first and second ends, to form a trailer chassis; transport means connected to said leg formed trailer chassis; said flrst means permitting disassembly of said leg formed trailer chassis; a central hub; a second means constructed to fasten the first ends of each of said legs to set hub to form an elevated support structure; and a third means adapted to draw the second ends of said legs together, whereby said central hub is elevated with respect to the second ends of said legs; said third means including a cable actuated means interconnecting said supporting legs.

11. An antenna structure comprising a tripod support joined at a central hub; said hub being constructed to receive a reflector carrying member; said tripod support 4including at least one leg pivotally fastened to said hub to permit angular separation thereof about said pivot; at least two of said tripod legs constructed to permit disengagement from said hub; means for fastening said disengaged legs in side-'by-side juxtaposed relationship directly to each other; said legs having top,` bottom and side surfaces; the side surfaces of adjacent ones of said legs in face-to-face relationship, with the top surfaces thereof lying substantially within a horizontal plane to define a trailer chassis; said leg formed trailer chassis including a transport means permanently connected to the bottom surface of at least one of said legs.

12. An antenna structure comprising a tripod support joined at a central hub; said hub 'being constructed to receive a reflector carrying member; said tripod support including at least one leg pivotally fastened to said hub to permit angular separation thereof about said pivot; at least two of said tripod legs constructed to permit disengagement fr0-m said hub; means for fastening said disengaged legs in side-by-side juxtaposed relationship directly to each other; said legs having top, bottom and side surfaces; the side surfaces of adjacent ones of said legs in face-to-face relationship, with the top surfaces thereof lying substantially within a horizontal plane to dene a trailer chassis; said leg formed trailer chassis including a transport means permanently connected to the bottom surface of at least one of said legs; elevating means to effect a decrease or increase of the angular separation of said pivoted leg with respect to said central hub, whereby said central hub is elevated or lowered, respectively.

13. An antenna structure comprising a tripod support joined at a central hub; said hub being constructed to receive a. reflector carrying member; said tripod support including at least one leg pivotally fastened to said hub to permit angular separation thereof about said pivot; at least two of said tripod legs constructed to permit disengagement from said hub; said disengaged legs adapted to form a trailer chassis; said leg formed trailer chassis including a transport means permanently connected to one of said legs; elevating means to effect a decrease or increase of the an-gular separation of said pivoted leg with respect to said central hub, whereby said central hub is elevated or lowered, respectively; said reflector being constructed of a plurality of individual members adapted to be assembled by bolt means; said leg formed trailer chassis being dimensioned to contain said individual reflector members prior to assembly of said reileetor; said trailer chassis containing all of the elements utilized in assembling said antenna system.

References Cited by the Examiner UNITED STATES PATENTS 383,198 5/1888 Tichenor et al. 189-11 2,283,049 5/1942 Cormier 52-117 2,344,390 3/1944 Cohen 52-117 X 2,474,250 6/ 1949 Howard 189-11 2,475,641 7/ 1949 Rosenberg 343--720 2,847,098 8/1958 Heinish 189-11 2,933,730 4/ 1960 Main 343--720 3,005,987 10/11961 Mack et al. 343--915 X 3,010,106 11/1961 Lippitt et al. 343--713 X FOREIGN PATENTS 914,238 6/ 1954 Germany.

ELI LIEBERMAN, Acting Primary Examiner. 

3. IN A MOBILE ANTENNA SYSTEM A SUPPORT STRUCTURE COMPRISING: A FIRST, SECOND AND THIRD LEG; A FIRST MEANS CONSTRUCTED TO FASTEN SAID LEGS DIRECTLY TO ONE ANOTHER IN SPACED PARALLEL RELATIONSHIP ALONG THE LENGTH THEREOF TO FORM A TRAILER CHASSIS; EACH OF SAID LEGS HAVING LONGILTUDINALLY EXTENDING TOP, BOTTOM AND SIDE SURFACES; SAID FIRST MEANS FASTENING SIDE SURFACES OF ADJACENT LEGS IN FACETO-FACE RELATIONSHIP, WITH A SIDE SURFACE OF SAID FIRST LEG FACING A SIDE SURFACE OF SAID SECOND LEG, AND A SIDE SURFACE OF SAID THIRD LEG FACING THE OPPOSED SIDE SURFACE OF SAID SECOND LEG; WHEEL AXLE TRANSPORT MEANS DIRECTLY SECURABLE TO THE BOTTOM SURFACE OF AT LEAST ONE OF SAID LEGS FOR MOVEMENT OF SAID LEG-FORMED TRAILER CHASSIS; AND A SECOND MEANS CONSTRUCTED TO FASTEN SAID LEGS IN A TRIPOD MANNER ABOUT A CENTRAL HUB; SAID CENTRAL HUB CONSTRUCTED TO RECEIVE AN ANTENNA REFLECTOR, FEED, AND REFLECTOR POSITIONING MEANS. 